Chapter 6Formation of Planetary SystemsOur Solar System and Beyond
The solar system exhibits clear patterns of composition and motion.
These patterns are far more important and interesting than numbers, names, and other trivia.
Planets are very tiny compared to
distances between them.
• Over 99.9% of solar system’s mass• Made mostly of H/He gas (plasma)• Converts 4 million tons of mass into energy each second
Sun
• Made of metal and rock; large iron core • Desolate, cratered; long, tall, steep cliffs• Very hot and very cold: 425°C (day), –170°C (night)
Mercury
• Nearly identical in size to Earth; surface hidden by clouds • Hellish conditions due to an extreme greenhouse effect• Even hotter than Mercury: 470°C, day and night
Venus
• An oasis of life• The only surface liquid water in the solar system• A surprisingly large moon
Earth and Moon to scale
Earth
• Looks almost Earth-like, but don’t go without a spacesuit!• Giant volcanoes, a huge canyon, polar caps, and more• Water flowed in the distant past; could there have been
life?
Mars
• Much farther from Sun than inner planets
• Mostly H/He; no solid surface
• 300 times more massive than Earth
• Many moons, rings
Jupiter
Jupiter’s moons can be as interesting as planets themselves, especially Jupiter’s four Galilean moons
• Io (shown here): Active volcanoes all over• Europa: Possible subsurface ocean• Ganymede: Largest moon in solar system• Callisto: A large, cratered “ice ball”
Saturn
• Giant and gaseous like Jupiter• Spectacular rings• Many moons, including cloudy Titan• Cassini spacecraft currently studying it
Rings are NOT solid; they are made of countless small chunks of ice and rock, each orbiting like a tiny moon.
Artist’s conception
The Rings of Saturn
• Smaller than Jupiter/Saturn; much larger than Earth
• Made of H/He gas and hydrogen compounds (H2O, NH3, CH4)
• Extreme axis tilt• Moons and rings
Uranus
• Similar to Uranus (except for axis tilt)
• Many moons (including Triton)
Neptune
Pluto and Eris
• Much smaller than other planets• Icy, comet-like composition• Pluto’s moon Charon is similar in size to Pluto
What features of our solar system provide clues to how it formed?
Motion of Large Bodies
• All large bodies in the solar system orbit in the same direction and in nearly the same plane.
• Most also rotate in that direction.
Two Major Planet Types
• Terrestrial planets are rocky, relatively small, and close to the Sun.
• Jovian planets are gaseous, larger, and farther from the Sun.
Swarms of Smaller Bodies
• Many rocky asteroids and icy comets populate the solar system.
Notable Exceptions
• Several exceptions to normal patterns need to be explained.
What theory best explains the features of our solar system?
According to the nebular theory, our solar system formed from a giant cloud of interstellar gas.
(nebula = cloud)
Where did the solar system come from?
Galactic Recycling
• Elements that formed planets were made in stars and then recycled through interstellar space.
Evidence from Other Gas Clouds• We can see
stars forming in other interstellar gas clouds, lending support to the nebular theory.
The Orion Nebula with Proplyds
What caused the orderly patterns of motion in our solar system?
Orbital and Rotational Properties of the Planets
Conservation of Angular Momentum
• The rotation speed of the cloud from which our solar system formed must have increased as the cloud contracted.
Rotation of a contracting cloud speeds up for the same reason a skater speeds up as she pulls in her arms.
Collapse of the Solar Nebula
• Collisions between particles in the cloud caused it to flatten into a disk.
Flattening
Collisions between gas particles in a cloud gradually reduce random motions.
Formation of Circular Orbits
Collisions between gas particles also reduce up and down motions.
Why does the Disk Flatten?
The spinning cloud flattens as it shrinks.
Formation of the Protoplanetary Disk
Disks Around Other Stars
• Observations of disks around other stars support the nebular hypothesis.
Why are there two major types of planets?
As gravity causes the cloud to contract, it heats up.
Conservation of Energy
Collapse of the Solar Nebula
Inner parts of the disk are hotter than outer parts.
Rock can be solid at much higher temperatures than ice.
Temperature Distribution of the Disk and the Frost Line
Inside the frost line: Too hot for hydrogen compounds to form ices
Outside the frost line: Cold enough for ices to form
Fig 9.5
Formation of Terrestrial Planets
• Small particles of rock and metal were present inside the frost line.
• Planetesimals of rock and metal built up as these particles collided.
• Gravity eventually assembled these planetesimals into terrestrial planets.
Tiny solid particles stick to form planetesimals.
Summary of the Condensates in the Protoplanetary Disk
Gravity draws planetesimals together to form planets.
This process of assembly is called accretion.
Summary of the Condensates in the Protoplanetary Disk
Accretion of Planetesimals
• Many smaller objects collected into just a few large ones.
Formation of Jovian Planets
• Ice could also form small particles outside the frost line.
• Larger planetesimals and planets were able to form.
• The gravity of these larger planets was able to draw in surrounding H and He gases.
The gravity of rock and ice in jovian planets draws in H and He gases.
Nebular Capture and the Formation of the Jovian Planets
Moons of jovian planets form in miniature disks.
Radiation and outflowing matter from the Sun — the solar wind — blew away the leftover gases.
The Solar Wind
Where did asteroids and comets come from?
Asteroids and Comets
• Leftovers from the accretion process• Rocky asteroids inside frost line• Icy comets outside frost line
Heavy Bombardment
• Leftover planetesimals bombarded other objects in the late stages of solar system formation.
Origin of Earth’s Water
• Water may have come to Earth by way of icy planetesimals from the outer solar system.
How do we explain the existence of our Moon and other exceptions to the rules?
Captured Moons
• The unusual moons of some planets may be captured planetesimals.
Giant Impact
Giant impact stripped matter from Earth’s crustGiant impact stripped matter from Earth’s crust
Stripped matter began to orbitStripped matter began to orbit
Then accreted into MoonThen accreted into Moon
Odd Rotation
• Giant impacts might also explain the different rotation axes of some planets.
Review of nebular theory
Thought Question
How would the solar system be different if the solar nebula had cooled with a temperature half its current value?
A. Jovian planets would have formed closer to the Sun.
B. There would be no asteroids.C. There would be no comets.D. Terrestrial planets would be larger.
Thought Question
How would the solar system be different if the solar nebula had cooled with a temperature half its current value?
A. Jovian planets would have formed closer to the Sun.
B. There would be no asteroids.C. There would be no comets.D. Terrestrial planets would be larger.
Thought Question
Which of these facts is NOT explained by the nebular theory?• There are two main types of planets: terrestrial
and jovian.• Planets orbit in the same direction and plane.• Asteroids and comets exist.• There are four terrestrial and four jovian planets.
Thought Question
Which of these facts is NOT explained by the nebular theory?• There are two main types of planets: terrestrial
and jovian.• Planets orbit in the same direction and plane.• Asteroids and comets exist.• There are four terrestrial and four jovian
planets.
When did the planets form?
• We cannot find the age of a planet, but we can find the ages of the rocks that make it up.
• We can determine the age of a rock through careful analysis of the proportions of various atoms and isotopes within it.
Radioactive Decay
• Some isotopes decay into other nuclei.
• A half-life is the time for half the nuclei in a substance to decay.
Thought Question
Suppose you find a rock originally made of potassium-40, half of which decays into argon-40 every 1.25 billion years. You open the rock and find 15 atoms of argon-40 for every atom of potassium-40. How long ago did the rock form?
A. 1.25 billion years agoB. 2.5 billion years agoC. 3.75 billion years agoD. 5 billion years ago
Thought QuestionSuppose you find a rock originally made of potassium-40, half of which decays into argon-40 every 1.25 billion years. You open the rock and find 15 atoms of argon-40 for every atom of potassium-40. How long ago did the rock form?
A. 1.25 billion years agoB. 2.5 billion years agoC. 3.75 billion years agoD. 5 billion years ago
Age dating of meteorites that are unchanged since they condensed and accreted tells us that the solar system is about 4.6 billion years old.
Dating the Solar System
Dating the Solar System
• Radiometric dating tells us that the oldest moon rocks are 4.4 billion years old.
• The oldest meteorites are 4.55 billion years old.
• Planets probably formed 4.5 billion years ago.
Important Point
• We have covered the material in chapter 6, sections 6.1 – 6.4.
• We will cover chapter 6, section 6.5, later in the course.
• The material in section 6.5 will not be included in the first midterm.